Airplane tooling

ABSTRACT

Briefly, the invention relates to jigs for placing aircraft component parts in assembled relationship and providing the pressure to bond them into a stresses skin construction. A generic concept to the invention is the use of selectively actuated pressure applying surfaces over the areas to be bonded while the parts are held in their proper relative locations. One portion of the invention relates to the bonding of an upper after fuselage section comprising flanged bulkhead sections and stringers and a stresses skin thereover in a single-stage jig having fluid expansible diaphragm over each of the areas to be joined, the fluid expansible diaphragms being in one-half of a jig which is pinned together to hold each of the bulkhead stringer and skin components in proper relation while providing a reaction force upon the application of the bonding pressure by means of the introduction of pressure into the diaphragms. A second portion of the invention relates to the construction of a skeleton of a wing having a main tubular spar and a trailing edge spar with flanged ribs of stamped metal, the jig including supports for the ribs and spars, individual resistance heating means for applying heat and pressure at each of the joints of the wing skeleton. The second-stage jig for bonding the skin to wing skeleton includes means for tensioning the skin over the skeleton as well as fluid pressure expansible means to provide the bonding pressure in all areas where the skin is bonded to the ribs and spars. The ribs of the wings have flanges into which transitory reinforcing means closely fit to prevent deflection of the flanges under the bonding pressure applied thereto, a transitory reinforcing means being segmented such that they may be pulled out through cutouts in the ribs of the wings after the bonding operation is completed. A further portion of the invention relates to bonding of a plurality of ribs and a torque tube of an aircraft control element in assembled relation by means of a liquid epoxy resin in a tube cradle and rib clamping jig which maintains the parallel relationship of the ribs at a fixed angular and lateral position with respect to the tube. The invention provides, in the second stage in the creation of a bonded aircraft control element, a jig which has pivoted contoured arms to clampingly engage the skin in areas in register over the ribs and trailing edge such that the areas to be bonded receive the proper bonding pressure. This pressure is supplied by means of a fluid pressure expansible means and manifold system compressed expansible means and manifold system connected thereto. In addition to the air frame, wing and control element jigs, the invention includes a jig for bonding a frame member for an airplane cutout to the periphery of the cutout which is a transitory self-supporting jig having opposing members which may be moved into and out of clamping engagement with the margin of the skin defining the cutout by means of screw means connecting the two opposing members. The opposing pressure applying surfaces of the two members includes at least one fluid pressure expansible means for application of the proper bonding pressure and a brief description.

June 13, 1972 R. L. JARVIS ET AL AIRPLANE TOOLING Original Filed Nov. 20, 1968 17 Sheets-Sheet l gfi:l:::r-Z" Z IL'L lo" FIG. I

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ATTORNEYS June 13, 1972 R. L. JARVIS ETAL 3,669,811

AIRPLANE TOOLING Original Filed Nov. 20, 1968 17 Sheets-Sheet 8 FIG.

INVENTORS RICHARD L. JARVIS WALT R KULLY AT ORNEYS June 13, 1972 R. L. JARVIS ETAL 3,6

AIRPLANE TOOLING Original Filed Nov. 20, 1968 17 Sheets-Sheet 4 x a FIG. IO

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INVENTORS RICHARD L. JARVIS ER KULLY ATTORNEYS June 13, 1972 R. L. JARVIS E AIRPLANE TOQLING Original Filed Nov. 20, 1968 17 Sheets-Sheet s FIG.

INVENJ'ORS RICHARD L. JARVIS WALTER KULLY ATTO YS June 13, 1972 R. JARVIS E AL 3,669,811

I AIRPLANE TOOLING Original Filed Nov. 20, 1968 17 Sheets-Sheet 6 INVENTORS w RICHARD L. JARVIS WALTER KU Y 98 F I a l sh M H 3 ATTORNEYS June 13, 1972 Original Filed Nov. 20, 1968 R. L. JARVIS ETAL AIRPLANE TOOLING l7 Sheets-Sheet 8 FIG. I6

INVENTORS RICHARD L. JARVIS WALTER KULLY A ORNEYS.

June 13, 1972 Original Filed Nov. 20, 1968 R. L. JARVIS ETAL AIRPLANE TOOLING 17 Sheets-Sheet 9 5, s2 2 g LL H ll MT HI F8 I m INVENTORS RICHARD L. JARVIS WALTER KULLY ATTORN EYS June 13, 1972 R. L. JARVIS ETAL AIRPLANE TOOLING Original Filed Nov. 20, 1968 17 Sheets-Sheet 10 vL s R E OD N TR M R NAE O UfiT wm m I I June 13, 1972 R. L. JARVIS ETAL 3,669,81l

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ATTORNEYS United States Patent Ofice 3,669,811 Patented June 13, 1972 3,669,811 AIRPLANE TOOLING Richard L. Jarvis, 24258 Gessner Road, North Olmstead, Ohio 44070, and Walter Kully, 2290 Tripplet Blvd., Akron, Ohio 44312 Original application Nov. 20, 1968, Ser. No. 777,362, now Patent No. 3,616,075, dated Oct. 26, 1971. Divided and this application May 21, 1970, Ser. No. 48,606

Int. Cl. B30b 3/04, 15/34 U.S. Cl. 156-583 6 Claims ABSTRACT OF THE DISCLOSURE Briefly, the invention relates to jigs for placing aircraft component parts in assembled relationship and providing the pressure to bond them into a stressed skin construction.

A generic concept to the invention is the use of selectively actuated pressure applying surfaces over the areas to be bonded while the parts are held in their proper relative locations.

One portion of the invention relates to the bonding of an upper after fuselage section comprising flanged bulkhead sections and stringers and a stressed skin thereover in a single-stage jig having fluid expansible diaphragm over each of the areas to be joined, the fluid expansible diaphragms being in one-half of a jig which is pinned together to hold each of the bulkhead stringer and skin components in proper relation while providing a reaction force upon the application of the bonding pressure by means of the introduction of pressure into the diaphragms.

A second portion of the invention relates to the construction of a skeleton of a wing having a main tubular spar and a trailing edge spar with flanged ribs of stamped metal, the jig including supports for the ribs and spars, individual resistance heating means for applying heat and pressure at each of the joints of the wing skeleton. The second-stage jig for bonding the skin to the wing skeleton includes means for tensioning the skin over the skeleton as well as fluid pressure expansible means to provide the bonding pressure in all areas where the skin is bonded to the ribs and spars. The ribs of the wings have flanges into which transitory reinforcing means closely fit to prevent deflection of the flanges under the bonding pressure applied thereto, a transitory reinforcing means being segmented such that they may be pulled out through cutouts in the ribs of the wings after the bonding operation is completed.

A further portion of the invention relates to bonding of a plurality of ribs and a torque tube of an aircraft control element in assembled relation by means of a liquid epoxy resin in a tube cradle and rib clamping jig which maintains the parallel relationship of the ribs at a fixed angular and lateral position with respect to the tube.

\The invention provides, in the second stage in the creation of a bonded aircraft control element, a jig which has pivoted contoured arms to clampingly engage the skin in areas in register over the ribs and trailing edge such that the areas to be bonded receive the proper bonding pressure. This pressure is supplied by means of a fluid pressure expansible means and manifold system con nected thereto.

In addition to the air frame, wing and control element jigs, the invention includes a jig for bonding a frame member for an airplane cutout to the periphery of the cutout which is a transitory self-supporting jig having opposing members which may be moved into and out of clamping engagement with the margin of the skin defining the cutout by means of screw means connecting the two opposing members. The opposing pressure applying surfaces of the two members include at least one fluid pressure expansible means for application of the proper bonding pressure and a brief description.

BACKGROUND OF THE INVENTION This appliction is a division of United States patent application Ser. No. 777,362, filed Nov. 20, 1968, now Pat. No. 3,616,075, issued Oct. 26, 1971.

This invention relates to light airplanes tooling and its use. Heretofore, small aircraft structures have been constructed using monocoque and semi-monocoque construction and a multitude of rivets to fasten the skins and bulkheads together. The bonded stressed-skin type of construction has been used for fuselage, wing and control element construction of larger airplanes; but, because of the difficulty and expense of providing the necessary tooling for properly locating the assembled parts and applying the required bonding pressures at the multitudes of joint locations therebet'ween, it has not been widely adopted in light airplane manufacture. As a consequence, most light airplanes of recent years have been of riveted or mechanical construction.

The present invention is a breakthrough in the economic use of bonded stressed-skin construction for the manufacture of light airplanes on a production basis. It is because of the novel tooling of this invention and its method of use that a light airplane of bonded stressedskin construction can now be economically produced. Such an airplane is clearly superior to those having a riveted skin both because of its smooth rivet-free appearance and its reduced drag.

Briefly, one type of airplane to be constructed by the novel tooling and method of the invention is of a construction in which the lower portion of the fuselage is made up of a bonded honeycomb sandwich structure reinforced by thin metal strips and angles. The particular design of this type of aircraft includes the use of a turtleback or unitary upper aft fuselage section having a stressed-skin construction bonded over a framework of thin metal bulkheads held in place by a central stringer.

The jig for the turtle-back portion of the fuselage has been provided such that two overlapped thin metal bulkhead sections are located and held firmly in place for bonding at a plurality of intermediate stations along the length of the jig. The aft bulkhead is of one piece. These are then tied together with a central upper stringer and the whole structure is uniformly bonded together with the metal skin stressed thereover in a single bonding operation.

A novel manner of providing a uniform bonding pressure and stressing the skin evenly over the bulkheads and stringer is provided. A thermosetting structural adhesive bonds the structural elements into a single rigid structure as they are held in proper assembled relationship by the novel tooling of the invention.

A tubular section projects entirely through the lower fuselage in such a manner that it provides for the connection and support of the wings at a proper dihedral angle. Each wing has a primary tubular spar which fits on the tubular section.

The wings and control surfaces of the airplane are also made of a bonded stressed-skin structure. The wing structure is primarily of a tubular spar construction having flanged thin transverse ribs with the stressed skin bonded thereto. A secondary channel-shaped spar joins the ends of the ribs adjacent the trailing edge. The control surfaces are similarly constructed utilizing single tubular spars and ribs. In the case of the wings, the ribs are made of flanged thin metal stampings, and in the case of the control surfaces, either stampings or honeycomb sandwich ribs of appropriate shape may be utilized.

Each of the airfoil structures is constructed in two stages: First, the skeleton is formed by assembling the ribs and the spars in an appropriate jig to accurately align and locate them. Then they are fixed in this assembled relation either by adhesive or mechanical fastening means. The skin is then stressed and bonded to the skeleton in a second jig designed to apply localized bonding pressures to the joints between the skin and ribs during the curing of the adhesive. These jigs have, over the areas of skin bonding to the skeleton, expansible pressure diaphragms which, after the two parts of the jig are clamped together, are inflated by fluid pressure to apply the necessary bonding pressure for the structural adhesive material being used. Special transitory reinforcing members to provide a reaction force and prevent distortion of the flanges during application of the bonding pressure are utilized. Provision is made in the wing jig for thermal expansion and contraction during the bonding operation. Examples of suitable adhesives for use are the types manufactured by Narmco Materials Division of Whittaker Corporation under the trademarks Metlbond 225 and Metlbond 328. Before bonding, all parts are surface prepared by treatment in a sulphuric acid sodium dichromate bath with an appropriate rinsing operation. These operations are performed prior to the assembly of the parts in the jig, and the parts are then carefully handled with cloth gloves to avoid contamination. The entire operation is performed in a controlled environment to further insure that the parts remain uncontaminated.

The turtle-back bulkhead section and stringers are set in a special single stage bonding fixture which is clamped with the skin laid thereover with all bonding points having to 20 psi. applied thereto. Thermocouples are attached to the structure at appropriate points and the jig is placed in the oven at a temperature of from 245 F. to 265 F. until all bonded joints are cured at 245 F. for 60 minutes. After the removal from the oven and a cooling down period, a complete inspection, including ultrasonic testing and mechanical testing of bonded specimens made simul-- taneously with the structure in the fixture, is performed. The controlsurface bonding operations are performed at the same temperature and pressure but, as stated before, in two stages, the first stage bonded rib and torque tube units being secured by means of an adhesive produced by the Minnesota Mining and Manufacturing 00., under the trademark 3M2214. This adhesive requires no pressure to perfect its bond.

The cutouts for the windows in the turtle-back por tion are provided by means of a novel workpiece supported clamping fixture. In order to provide the frames about the window cutouts, the angular frame members of L- shaped cross-section are bonded to the periphery of the cutouts. The clamping fixture for this purpose has forceapplying surfaces on the opposing faces of two separate jaw portions which are bolted in clamping engagement through the cutout with the marginal portion of the skin and the frame therebetween. At leastone force-applying surface of the clamping fixture has a pressure expansible diaphragm member mounted in a groove thereof so that, after the fixture parts are bolted into place, air pressure may be introduced into the expansible diaphragm. This applies a uniform bonding pressure to all points of the adhesive joint between the skin and the frame.

BRIEF DESCRIPTION OF THE INVENTION Briefly, the invention relates to jigs for placing aircraft component parts in assembled relationship and providing the pressure to bond them into a stressed skin construction.

A generic concept to the invention is the use of selectively actuated pressure applying surfaces over the areas to be bonded while the parts are held in their proper relative locations.

One portion of the invention relates to the bonding of an upper aft fuselage section comprising flanged bulkhead sections and stringers and a stressed skin thereover in a single-stage jig having fluid exapnsible diaphragm over each of the areas to be joined, the fluid exapnsible diaphragms being in one halfof a jig which is pinned together to hold each of the bulkhead stringer and skin components in proper relation while providing a reaction force upon the application of the bonding pressure by means of the introduction of pressure into the diaphragms.

A second portion of the invention relates to the construction of a skeleton of a wing having a main tubular spar and a trailing edge spar with flanged ribs of stamped metal, the jig including supports for the ribs and spars, individual resistance heating means for applying heat and pressure at each of the joints of the wing skeleton. The second-stage jig for bonding the skin to the wing skeleton includes a means for tensioning the skin over the skeleton as well as fluid pressure expansible means to provide the bonding pressure in all areas where the skin is bonded to the ribs and spars. The ribs of the wings have flanges into which transitory reinforcing means closely fit to prevent deflection of the flanges under the bonding pressure applied thereto, a transitory reinforcing means being segmented such that they may be pulled out through cutouts in the ribs of the wings after the bonding operation is completed.

A further portion of the invention relates to bonding of a plurality of ribs and a torque tube of an aircraft control element in assembled relation by means of a liquid epoxy resin in a tube cradle and rib clamping jig which maintains the parallel relationship of the ribs at a fixed angular and lateral position with respect to the tube.

The invention provides, in the second stage in the creation of a bonded aircraft control element, a jig which has pivoted contoured arms clampingly to engage the skin in areas in register over the ribs and trailing edge such that the areas to be bonded receive the proper bonding pressure. This pressure is supplied by means of a fluid pressure expansible means and manifold system connected thereto.

In addition tothe air frame, wing and control element jigs, the invention includes a jig for bonding a frame member for an airplane cutout to the periphery of the cutout which is a transitory self-supporting jig having opposing members which may be moved into and out of clamping engagement with the margin of the skin defining the cutout by means of screw means connecting the two opposing members. The opposing pressure applying surfaces of the two members include at lease one fluid pressure expansible means for application of the proper bonding pressure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 represents a plan view of the upper aft fuselage assembly or turtle-back of a light airplane constructed using the tooling and method of this invention.

FIG. 2 represents a side elevation view of the turtleback of FIG. 1.

FIG. 3 represents a front elevation of the turtleback of FIG. 1.

FIG. 4 represents a fragmentary view taken along the line 44 of FIG. 3 with portions of the parts broken away for clarity.

FIG. 5 represents a cross-sectional side elevation view of the lower portion of the turtle-back jig with the bulkhead sections and skin in place thereon.

F1gIG. 6 is an enlarged detailed view of a portion of FIG. 7 is a schematic side elevation view of the turtle-back jig with the top portion assembled to the bottom portion and the skin and bulkheads in place for bonding showing the manifolding for the fluid expansible pressure diaphragms.

FIG. 8 is an enlarged detailed cross-sectional elevation view of the assembled turtle-back jig of FIG. 7.

FIG. 9 is a cross-sectional view taken along the line 99 of FIG. 8 during the application of fluid pressure.

FIG. 10 is a cross-sectional view taken along the line 1010 of FIG. 8.

FIG. 11 is a side elevation view of the first stage bonding jig for the wing showing the spars and ribs in place.

FIG. 12 is a cross-sectional elevation view taken along the line 12-12 of FIG. 11.

FIG. 13 is a detailed side elevation view taken along the line 13-13 of FIG. 12.

FIG. 14 is a fragmentary cross-sectional view taken along line 14-14 of FIG. 13.

FIG. 15 is a detailed cross-sectional elevation view of a portion of FIG. 13 with certain other portions shown in FIG. 14 omitted for clarity.

FIG. 16 is a schematic view of the fluid actuated heating clamps of the jig of FIGS. 11 to 15.

FIG. 17 is a side-elevation view of the second stage jig for bonding the wing with the skin and transitory reinforcing members in place.

FIG. 18 is a cross-sectional elevation view of the monocoque wing structure of the invention prior to insertion in the jig of FIG. 17.

FIG. 19 is a cross-sectional elevation view taken along the line 19-19 of FIG. 17.

FIG. 20 is a plan view of a typical control surface.

FIG. 21 is a cross-sectional view taken along the line 21-21 of FIG. 20.

FIG. 22 is a detailed cross-sectional view of the trailing edge of the control surface taken along the lines 22-22 of FIG. 20.

FIG. 23 is a plan view of the spar and ribs of the control surface of FIG. 20 in its first-stage bonded jig.

FIG. 24 is an end elevation view of the structure of FIG. 23.

FIG. 25 is a top plan view of the second-stage bonding jig for the control element illustrated in FIG. 20.

FIG. 26 is an end elevation view of the structure shown in FIG. 25.

FIG. 27 is a fragmentary cross-sectional view taken along the lines 27--27 of FIG. 26.

FIG. 28 is a fragmentary elevation view of a window in the turtle-back of FIGS. 1 to 3.

FIG. 29 is a side elevation view of the jig in place for applying the bonding pressure for the window frame illustrated in FIG. 28.

FIG. 30 is a cross-sectional view taken along the line 3030 of FIG. 29.

FIG. 31 is a cross-sectional view taken along the line 31--3'1 of FIG. 28.

FIG. 32 is a side elevational view of the second-stage bonding jig for applying the skin to the riveted skeleton structure of a stabilizer or fin of the airplane with certain of the parts broken away for clarity.

FIG. 33 is an end elevational view with structure of FIG. 32.

FIG. 34 is a cross-sectional elevational view of the structure of FIG. 32 taken along the line 3434 with the righthand portion shown in alternative position in phantom.

PREFERRED EMBODIMENT In the embodiment of the invention illustrated in the drawings, the numeral 1 generally designates the upper aft fuselage assembly or turtle-back. The turtle-back 1 is of semi-monocoque construction having front and rear flanged metal bulkheads 2 and 3, respectively, and intermediate bulkheads 4 and 5. Bulkheads 4 and are made in two flanged sections as best shown in connection with FIG. 4 with a left-hand section 7 overlapping the righthand section 8 at the inner ends thereof. A channel-shaped stringer 10 interconnects the bulkheads 2, 3, 4 and 5. Notches or slots are provided in the overlapping inner ends of the bulkhead sections making up bulkheads 4 and 5 to permit passage of the legs of the channel-shaped stringer 10 therethrough in a manner more clearly seen in FIG. 4. The stringer 10 overlaps the bulkheads 2 and 3 and is bonded thereto for rigidity of the semi-monocoque structure. At the same time, an aluminum skin 15 of 0.020 inch thickness, for example, is bonded under heat and pressure to the stringer 10 and the peripheral flanges of bulkheads 2, 3, 4 and 5. In a separate operation to be described later the turtle-back is provided with windows 12 on either side thereof which are framed by a bonded metal member 13 having an angular cross-section.

The bulkheads, stringer and skin are assembled and bonded under pressure in the jig shown in FIGS. 5 through 10. The lower half of the turtle-back bonding jig is generally designated by the numeral 16. The jig is generally designated by the numeral 16. The jig 16 has a pair of horizontal support members 18 upon which a plurality of upstanding bulkhead support members 20 are located. The flanged bulkheads 2, 3', 4 and 5 are located in proper position with their peripheral flanges resting on the top edges of support members 20. They are held in place by toggle clamps 22.

The toggle clamps 22 are of a conventional type having a projecting manually operated lever 23 of a general L- shaped structure. The lever 23 is pivotally connected at the junction of the two legs of the L, 23a and 23b respectively, to a link 24. At the end of the leg 23b, opposite the exposed manually operated leg 23a, is a pivotal connection with a clamp base member 26. The link 24 is in pivotal engagement with the force applying arm 27 which is, in turn, pivotally mounted on the clamp base member 26. Projecting from the arm 26 is the force-applying pad 28 which engages the bulkheads and bulkhead sections to hold them in place on supports 20. Bolts 29 secure the base 26 of the clamp to the support 20.

A view of FIG. 8, for example, will illustrate the operation of the clamp 22. By moving lever 23 upwardly about the pivotal connection of the leg 23b to the base 27, a clamping force will be applied to clamp the flanged bulkhead sections 7 and 8 in place on the bulkhead support 20 of the jig 16. The force will be removed upon movement of the lever 23 in the opposite or downward direction.

Each of the upstanding support members 20 is reinforced and held in position by an intermediate plate member 30. This plate member assures alignment of the top portions of the upstanding support members 20. Along the top of the plate member 30, a novel stringer support and clamping mechanism is provided.

This mechanism comprises fixed blocks 31 fastened to the top edge of the plate 30 by means of bolts 32. There is one fixed block for each bay between bulkhead support members 20. Each of the fixed members 31 have a forwardly extending tapered nose portion 33. Adjacent each of the tapered nose portions, and tapered in a complimentary shape, is a movable segment portion 35 for association with the fixed member 31. Relative longitudinal motion between movable member 35 and a fixed member 31 produces an upward movement of the member 35. The longitudinal motion is created by a manually operated actuator 36 tied by links 37 to each of the movable members 35. A plurality of blocks 39 fastened to the top edge of the plate 30 projecting upwardly therefrom define a channel for each of the movable members 35 to maintain them in alignment with their respective fixed members 31 during longitudinal movement. Thus, it will be seen that movement of the actuator 36 by means of longitudinally pushing it at its end projecting beyond the front bulkhead support 20 until a notch 34 engages support 20 will create longitu- 

